Office: BPB 412
Mailing Address: Department of Ecology and Evolutionary Biology
University of Connecticut
75 N. Eagleville Road Unit 3043
Storrs, CT 06269
M.S. University of South Florida, Integrative Biology, December 2008.
Thesis Advisor: Stephen Deban
Thesis Title: The Role of Abiotic And Biotic Factors In Suspension Feeding Mechanics Of Xenopus Tadpoles
My research lies primarily in the fields of vertebrate morphology, physiology and biomechanics. I am interested in the form and function of
animal movement, and how these principles change through ontgony and evolution. Generally, I focus my work on reptiles and amphibians, but I am open to
potential work outside of these systems.
Fluid Mechanics of Tongue Flicking in Snakes
Under the guidance of Kurt Schwenk, my dissertation is focused on the fluid mechanics of tongue flicking in snakes. Snakes are well known for their forked tongues, and it has been proposed that this mechanism allows for detection of a chemical gradient. Differing concentration of odor particles would provide individuals with the ability to determine the relative direction of the odor source. However, snakes sample the environment for these odor cues by rapidly extending and oscillating the tongue. This has the potential to obscure the odor source by inducing mixing of the air around the tongue. Enough turbulence will prevent the organism from determining directionality of the source. Using high imaging and visualization techniques, I aim to describe the movement of air around the tongue of snakes during the tongue flicking behavior, and determine if snakes possess the ability to discern direction. I also am investigating the potential effects of ecological, morphological, and behavioral factors that may modulate tongue flicking.
Jumping in Plethodontid Salamanders
Plethodontidae, the lungless salamanders, is well studied for the myriad of unique behaviors and morphologies. Aposematic coloration, toxic skin
secretions, and ballistic tongue feeding are just some of the mechanisms under investigation around the world. My interest in this system is the
ability of these salamanders to propel themselves into the air. Unlike most jumpers, plethodontid salamanders don't possess large hindlimbs suited
for this task. Instead, it appears that these salamanders bend and rapidly straighten their torso, providing the momentum required for the jump.
In addition to describing this behavior, I'm interested in seeing (using EMG) how the axial musculature powers this ability, as well the role the
hind limbs do play in this matter.
May 2014 - EEB 3898 "Field Herpetology"
Spring 2014 - EEB 3894 "Current Research in Ecology and Evolutionary Biology"
Fall 2013 - EEB 3254/5254 "Mammalogy"
Summer 2013 - BSC 1107 "Principles Biology I"
Spring 2013 - BSC 1102 "Foundations of Biology"
Fall 2012 - EEB 3273 "Comparative Vertebrate Anatomy"
Spring 2012 - BSC 1108 "Principles of Biology II"
Fall 2011 - BSC 1108 "Principles of Biology II"
Spring 2011 - BSC 1108 "Principles of Biology II"
Fall 2010 - EEB 3273 "Comparative Vertebrate Anatomy"
Spring 2010 - BSC 1108 "Principles of Biology II"
Fall 2009 - BSC 1108 "Principles of Biology II"
Spring 2009-Present: Reviewer, Journal of Experimental Zoology
Fall 2009-Spring 2012: Senator, Graduate Student Senate
Spring 2010-Present: Reviewer, Journal of Morphology
Fall 2010-Spring 2012: President, EEB Graduate Student Association
Fall 2011-Present: Reviewer, Journal of Comparative Psychology
Fall 2012-Present: Reviewer, Journal of Experimental Biology
American Society of Icthyologists and Herpetologists
Society for Integrative and Comparative Biology
Society for the Study of Amphibians and Reptiles
Bold indicates undergraduate/mentee authors
Ryerson, WG, Hessel, A, and Whitenack, LB. pending revisions. Comparative jumping mechanics in plethodontid salamanders. J. Exp. Zool.
Ryerson, WG and Horwitz, S. 2014. Sidewinding in the green anaconda. Herp. Review. 45, 37-38.
Ryerson, WG. 2013. Jumping in the salamander, Desmognathus ocoee. Copeia. 2013 (3), 512-516.
Ryerson, WG and Schwenk, K. 2012. A simple, inexpensive system for digital particle image velocimetry (DPIV) in biomechanics. J. Exp. Zool. 317A, 127-140. (with cover)